Devices for heating and charging energy storage devices at very low temperatures

1. A heating circuit for an energy storage device having a core with an electrolyte, the energy storage device having inputs, characteristics of a capacitance across the electrolyte and the core, and internal surface capacitance between the inputs which can store electric field energy between internal electrodes of the energy storage device that are coupled to the inputs, the battery heating circuit comprising: at least one power supply, separate from the energy storage device, configured to generate a positive input voltage and a negative input voltage, wherein a positive terminal of the power supply is connected to a negative terminal of the energy storage device and to ground; and a controller configured to switch between the positive input voltage and the negative input voltage coupled to one of the inputs at a frequency sufficient to effectively short the internal surface capacitance of the energy storage device to generate heat and raise a temperature of the electrolyte, the controller being further configured to discontinue the switching when the temperature of the electrolyte and/or the energy storage device is above a predetermined temperature that is considered sufficient to increase a charging efficiency of the energy storage device.

2. The heating circuit of claim 1 , wherein the predetermined temperature is a first predetermined temperature, wherein the controller is further configured to start the switching between the positive input voltage and the negative input voltage provided to the one of the inputs in response to a second predetermined temperature that is considered to reduce the charging efficiency of the energy storage device.

3. The heating circuit of claim 2 , comprising a temperature sensor configured to provide a signal to the controller, wherein the signal is based on a sensed temperature of the electrolyte and/or a surface of the energy storage device.

4. The heating circuit of claim 3 , wherein the temperature sensor is a Resistance Temperature Detector (RTD).

5. The heating circuit of claim 1 , comprising a temperature sensor configured to provide a signal to the controller, wherein the signal is based on a sensed temperature of the electrolyte and/or a surface of the energy storage device.

6. The heating circuit of claim 5 , wherein the temperature sensor is a Resistance Temperature Detector (RTD).

7. The heating circuit of claim 1 , wherein the controller is further configured to change the switching frequency at different electrolyte battery temperatures.

8. The heating circuit of claim 1 , comprising a first switch and a second switch, wherein the controller is configured to control the first switch to provide the positive input voltage directly to the one input through the first switch and is configured to control the second switch to provide the negative input voltage directly to the one input through the second switch, wherein during the switching, the controller is further configured to simultaneously couple the positive input voltage to the one input through operation of the first switch and decouple the negative input voltage from the one input through operation of the second switch during a first time interval and thereafter, simultaneously decouple the positive input voltage from the one input through operation of the first switch and couple the negative input voltage to the one input during a second time interval through operation of the second switch, wherein the controller is further configured to repeat the first interval and the second interval at the frequency sufficient to effectively short the internal surface capacitance of the energy storage device.

9. The heating circuit of claim 8 , wherein the first switch is configured to couple the positive input voltage to the one input when a first switching voltage provided by the controller is above zero volts.

10. The heating circuit of claim 9 , wherein the second switch is configured to decouple the negative input voltage from the one input when the first switching voltage provided by the controller is above zero volts.

11. The heating circuit of claim 10 , wherein the first switch is configured to decouple the one input from the positive input voltage and the second switch is configured to decouple the one input from the negative input voltage when the first switching voltage provided by the controller is zero volts.

12. The heating circuit of claim 8 , comprising a voltage divider circuit configured to set the positive input voltage and the negative input voltage such that nearly the same charge of the energy storage device occurs during the first time interval as discharge from the energy storage device occurs during the second time interval.

13. The heating circuit of claim 1 , wherein the controller is configured to obtain at least one of a measurement and an approximation of the temperature of the electrolyte.

14. The heating circuit of claim 1 , wherein the controller is configured to determine an approximation of the temperature of the electrolyte by applying an initial charging input to the energy storage device, measuring a rate of charging using the initial charging input, and determining a charging rate at the initial charging input, wherein if a rate of charging is determined to be less than a predetermined charging rate, the electrolyte temperature is approximated as being less than the predetermined temperature.

15. The heating circuit of claim 1 , wherein the controller is configured to determine the temperature of the electrolyte and/or energy storage device periodically.

16. The heating circuit of claim 1 , comprising a first AC to DC converter configured to produce the positive input voltage from an AC source and a second AC to DC converter configured to produce the negative input voltage from the AC source.

17. The heating circuit of claim 1 , wherein the controller is further configured to obtain an energy storage type for the energy storage device, wherein the controller is further configured to determine the predetermined temperature based on the obtained energy storage type, wherein different energy storage types correlate with corresponding predetermined temperatures.

18. The heating circuit of claim 17 , wherein the energy storage type is a lithium ion battery or a supercapacitor.

19. The charging circuit of claim 1 , wherein the controller switches between the positive input voltage and the negative input voltage coupled to the one of the inputs to produce a square waved shaped voltage to the one of the inputs at the frequency sufficient to effectively short the internal surface capacitance of the energy storage device to generate heat and raise the temperature of the electrolyte.

20. A charging circuit for an energy storage device having a core with an electrolyte, the energy storage device further having inputs, characteristics of a capacitance across the electrolyte and the core and internal surface capacitance between the inputs which can store electric field energy between internal electrodes of the energy storage device that are coupled to the inputs, the charging circuit comprising: at least one power supply, separate from the energy storage device, configured to generate a positive input voltage and a negative input voltage, wherein a positive terminal of the power supply is connected to a negative terminal of the energy storage device and to ground; and a controller configured to switch between the positive input voltage and the negative input voltage provided to one of the inputs at a frequency sufficient to effectively short the internal surface capacitance of the energy storage device to generate heat and raise a temperature of the electrolyte, periodically obtain a measurement that correlates to the temperature of the electrolyte, initiate the switching when the measurement indicates that the temperature of the electrolyte is below a low temperature threshold that is considered to at least reduce the charging efficiency of the energy storage device, discontinue the switching when the measurement indicates that the temperature of the electrolyte is above a high temperature threshold that is considered sufficient to increase a charging efficiency of the energy storage device, wherein the low temperature threshold is a lower temperature than the high temperature threshold, and provide the positive input voltage to the one input to charge the energy storage device while the measurement indicates that the temperature of the electrolyte is above the high temperature threshold.

21. The charging circuit of claim 20 , wherein the controller switches between the positive input voltage and the negative input voltage coupled to the one of the inputs to produce a square waved shaped voltage to the one of the inputs at the frequency sufficient to effectively short the internal surface capacitance of the energy storage device to generate heat and raise the temperature of the electrolyte.

22. The charging circuit of claim 20 , comprising a first switch and a second switch, wherein the controller is configured to control the first switch to provide the positive input voltage directly to the one input through the first switch and is configured to control the second switch to provide the negative input voltage directly to the one input through the second switch, wherein during the switching, the controller is further configured to simultaneously couple the positive input voltage to the one input through operation of the first switch and decouple the negative input voltage from the one input through operation of the second switch during a first time interval and thereafter, simultaneously decouple the positive input voltage from the one input through operation of the first switch and couple the negative input voltage to the one input during a second time interval through operation of the second switch, wherein the controller is further configured to repeat the first interval and the second interval at the frequency sufficient to effectively short the internal surface capacitance of the energy storage device.